esphome/esphome/components/qmc5883l/qmc5883l.cpp

#include "qmc5883l.h"
#include "esphome/core/log.h"

namespace esphome {
namespace qmc5883l {

static const char *TAG = "qmc5883l";
static const uint8_t QMC5883L_ADDRESS = 0x0D;

static const uint8_t QMC5883L_REGISTER_DATA_X_LSB = 0x00;
static const uint8_t QMC5883L_REGISTER_DATA_X_MSB = 0x01;
static const uint8_t QMC5883L_REGISTER_DATA_Y_LSB = 0x02;
static const uint8_t QMC5883L_REGISTER_DATA_Y_MSB = 0x03;
static const uint8_t QMC5883L_REGISTER_DATA_Z_LSB = 0x04;
static const uint8_t QMC5883L_REGISTER_DATA_Z_MSB = 0x05;
static const uint8_t QMC5883L_REGISTER_STATUS = 0x06;
static const uint8_t QMC5883L_REGISTER_TEMPERATURE_LSB = 0x07;
static const uint8_t QMC5883L_REGISTER_TEMPERATURE_MSB = 0x08;
static const uint8_t QMC5883L_REGISTER_CONTROL_1 = 0x09;
static const uint8_t QMC5883L_REGISTER_CONTROL_2 = 0x0A;
static const uint8_t QMC5883L_REGISTER_PERIOD = 0x0B;

void QMC5883LComponent::setup() {
  ESP_LOGCONFIG(TAG, "Setting up QMC5883L...");
  // Soft Reset
  if (!this->write_byte(QMC5883L_REGISTER_CONTROL_2, 1 << 7)) {
    this->error_code_ = COMMUNICATION_FAILED;
    this->mark_failed();
    return;
  }
  delay(10);

  uint8_t control_1 = 0;
  control_1 |= 0b01 << 0;  // MODE (Mode) -> 0b00=standby, 0b01=continuous
  control_1 |= this->datarate_ << 2;
  control_1 |= this->range_ << 4;
  control_1 |= this->oversampling_ << 6;
  if (!this->write_byte(QMC5883L_REGISTER_CONTROL_1, control_1)) {
    this->error_code_ = COMMUNICATION_FAILED;
    this->mark_failed();
    return;
  }

  uint8_t control_2 = 0;
  control_2 |= 0b0 << 7;  // SOFT_RST (Soft Reset) -> 0b00=disabled, 0b01=enabled
  control_2 |= 0b0 << 6;  // ROL_PNT (Pointer Roll Over) -> 0b00=disabled, 0b01=enabled
  control_2 |= 0b0 << 0;  // INT_ENB (Interrupt) -> 0b00=disabled, 0b01=enabled
  if (!this->write_byte(QMC5883L_REGISTER_CONTROL_2, control_2)) {
    this->error_code_ = COMMUNICATION_FAILED;
    this->mark_failed();
    return;
  }

  uint8_t period = 0x01;  // recommended value
  if (!this->write_byte(QMC5883L_REGISTER_PERIOD, period)) {
    this->error_code_ = COMMUNICATION_FAILED;
    this->mark_failed();
    return;
  }
}
void QMC5883LComponent::dump_config() {
  ESP_LOGCONFIG(TAG, "QMC5883L:");
  LOG_I2C_DEVICE(this);
  if (this->error_code_ == COMMUNICATION_FAILED) {
    ESP_LOGE(TAG, "Communication with QMC5883L failed!");
  }
  LOG_UPDATE_INTERVAL(this);

  LOG_SENSOR("  ", "X Axis", this->x_sensor_);
  LOG_SENSOR("  ", "Y Axis", this->y_sensor_);
  LOG_SENSOR("  ", "Z Axis", this->z_sensor_);
  LOG_SENSOR("  ", "Heading", this->heading_sensor_);
}
float QMC5883LComponent::get_setup_priority() const { return setup_priority::DATA; }
void QMC5883LComponent::update() {
  uint8_t status = false;
  this->read_byte(QMC5883L_REGISTER_STATUS, &status);

  uint16_t raw_x, raw_y, raw_z;
  if (!this->read_byte_16_(QMC5883L_REGISTER_DATA_X_LSB, &raw_x) ||
      !this->read_byte_16_(QMC5883L_REGISTER_DATA_Y_LSB, &raw_y) ||
      !this->read_byte_16_(QMC5883L_REGISTER_DATA_Z_LSB, &raw_z)) {
    this->status_set_warning();
    return;
  }

  float mg_per_bit;
  switch (this->range_) {
    case QMC5883L_RANGE_200_UT:
      mg_per_bit = 0.0833f;
      break;
    case QMC5883L_RANGE_800_UT:
      mg_per_bit = 0.333f;
      break;
    default:
      mg_per_bit = NAN;
  }

  // in µT
  const float x = int16_t(raw_x) * mg_per_bit * 0.1f;
  const float y = int16_t(raw_y) * mg_per_bit * 0.1f;
  const float z = int16_t(raw_z) * mg_per_bit * 0.1f;

  float heading = atan2f(0.0f - x, y) * 180.0f / M_PI;
  ESP_LOGD(TAG, "Got x=%0.02fµT y=%0.02fµT z=%0.02fµT heading=%0.01f° status=%u", x, y, z, heading, status);

  if (this->x_sensor_ != nullptr)
    this->x_sensor_->publish_state(x);
  if (this->y_sensor_ != nullptr)
    this->y_sensor_->publish_state(y);
  if (this->z_sensor_ != nullptr)
    this->z_sensor_->publish_state(z);
  if (this->heading_sensor_ != nullptr)
    this->heading_sensor_->publish_state(heading);
}

bool QMC5883LComponent::read_byte_16_(uint8_t a_register, uint16_t *data) {
  bool success = this->read_byte_16(a_register, data);
  *data = (*data & 0x00FF) << 8 | (*data & 0xFF00) >> 8;  // Flip Byte oder, LSB first;
  return success;
}

}  // namespace qmc5883l
}  // namespace esphome
Add QMC5883L Sensor + Improvements to HMC5883L (#671) * Add QMC5883L and Updated HMC5883L * add tests * changed to oversampling * fix pylint * fix private method * typo fix * fix protected method * Clean up code and PR recomendations * fix tests * remote file * fix qmc oversampling unit * Remove hmc5883l config logging Either the units are converted to the user values like 1x, 8x oversampling or not printed at all. Printing the machine-value of these is only confusing users. * Changes for validate_enum Move stuff that can be done beforehand out of the bound function, use text_type for py2/3 compatability. * Remove unused constant * Remove duplicate tests * Repeat remove config print * remove changes to test2 since bin is to large * Add comment to HMC5583L Co-authored-by: Timothy Purchas <timothy@TPF.local> Co-authored-by: Otto Winter <otto@otto-winter.com> 2019-11-26 18:43:11 +01:00			`#include "qmc5883l.h"`
			`#include "esphome/core/log.h"`

			`namespace esphome {`
			`namespace qmc5883l {`

			`static const char *TAG = "qmc5883l";`
			`static const uint8_t QMC5883L_ADDRESS = 0x0D;`

			`static const uint8_t QMC5883L_REGISTER_DATA_X_LSB = 0x00;`
			`static const uint8_t QMC5883L_REGISTER_DATA_X_MSB = 0x01;`
			`static const uint8_t QMC5883L_REGISTER_DATA_Y_LSB = 0x02;`
			`static const uint8_t QMC5883L_REGISTER_DATA_Y_MSB = 0x03;`
			`static const uint8_t QMC5883L_REGISTER_DATA_Z_LSB = 0x04;`
			`static const uint8_t QMC5883L_REGISTER_DATA_Z_MSB = 0x05;`
			`static const uint8_t QMC5883L_REGISTER_STATUS = 0x06;`
			`static const uint8_t QMC5883L_REGISTER_TEMPERATURE_LSB = 0x07;`
			`static const uint8_t QMC5883L_REGISTER_TEMPERATURE_MSB = 0x08;`
			`static const uint8_t QMC5883L_REGISTER_CONTROL_1 = 0x09;`
			`static const uint8_t QMC5883L_REGISTER_CONTROL_2 = 0x0A;`
			`static const uint8_t QMC5883L_REGISTER_PERIOD = 0x0B;`

			`void QMC5883LComponent::setup() {`
			`ESP_LOGCONFIG(TAG, "Setting up QMC5883L...");`
			`// Soft Reset`
			`if (!this->write_byte(QMC5883L_REGISTER_CONTROL_2, 1 << 7)) {`
			`this->error_code_ = COMMUNICATION_FAILED;`
			`this->mark_failed();`
			`return;`
			`}`
			`delay(10);`

			`uint8_t control_1 = 0;`
			`control_1 \|= 0b01 << 0; // MODE (Mode) -> 0b00=standby, 0b01=continuous`
			`control_1 \|= this->datarate_ << 2;`
			`control_1 \|= this->range_ << 4;`
			`control_1 \|= this->oversampling_ << 6;`
			`if (!this->write_byte(QMC5883L_REGISTER_CONTROL_1, control_1)) {`
			`this->error_code_ = COMMUNICATION_FAILED;`
			`this->mark_failed();`
			`return;`
			`}`

			`uint8_t control_2 = 0;`
			`control_2 \|= 0b0 << 7; // SOFT_RST (Soft Reset) -> 0b00=disabled, 0b01=enabled`
			`control_2 \|= 0b0 << 6; // ROL_PNT (Pointer Roll Over) -> 0b00=disabled, 0b01=enabled`
			`control_2 \|= 0b0 << 0; // INT_ENB (Interrupt) -> 0b00=disabled, 0b01=enabled`
			`if (!this->write_byte(QMC5883L_REGISTER_CONTROL_2, control_2)) {`
			`this->error_code_ = COMMUNICATION_FAILED;`
			`this->mark_failed();`
			`return;`
			`}`

			`uint8_t period = 0x01; // recommended value`
			`if (!this->write_byte(QMC5883L_REGISTER_PERIOD, period)) {`
			`this->error_code_ = COMMUNICATION_FAILED;`
			`this->mark_failed();`
			`return;`
			`}`
			`}`
			`void QMC5883LComponent::dump_config() {`
			`ESP_LOGCONFIG(TAG, "QMC5883L:");`
			`LOG_I2C_DEVICE(this);`
			`if (this->error_code_ == COMMUNICATION_FAILED) {`
			`ESP_LOGE(TAG, "Communication with QMC5883L failed!");`
			`}`
			`LOG_UPDATE_INTERVAL(this);`

			`LOG_SENSOR(" ", "X Axis", this->x_sensor_);`
			`LOG_SENSOR(" ", "Y Axis", this->y_sensor_);`
			`LOG_SENSOR(" ", "Z Axis", this->z_sensor_);`
			`LOG_SENSOR(" ", "Heading", this->heading_sensor_);`
			`}`
			`float QMC5883LComponent::get_setup_priority() const { return setup_priority::DATA; }`
			`void QMC5883LComponent::update() {`
			`uint8_t status = false;`
			`this->read_byte(QMC5883L_REGISTER_STATUS, &status);`

			`uint16_t raw_x, raw_y, raw_z;`
			`if (!this->read_byte_16_(QMC5883L_REGISTER_DATA_X_LSB, &raw_x) \|\|`
			`!this->read_byte_16_(QMC5883L_REGISTER_DATA_Y_LSB, &raw_y) \|\|`
			`!this->read_byte_16_(QMC5883L_REGISTER_DATA_Z_LSB, &raw_z)) {`
			`this->status_set_warning();`
			`return;`
			`}`

			`float mg_per_bit;`
			`switch (this->range_) {`
			`case QMC5883L_RANGE_200_UT:`
			`mg_per_bit = 0.0833f;`
			`break;`
			`case QMC5883L_RANGE_800_UT:`
			`mg_per_bit = 0.333f;`
			`break;`
			`default:`
			`mg_per_bit = NAN;`
			`}`

			`// in µT`
			`const float x = int16_t(raw_x) * mg_per_bit * 0.1f;`
			`const float y = int16_t(raw_y) * mg_per_bit * 0.1f;`
			`const float z = int16_t(raw_z) * mg_per_bit * 0.1f;`

			`float heading = atan2f(0.0f - x, y) * 180.0f / M_PI;`
			`ESP_LOGD(TAG, "Got x=%0.02fµT y=%0.02fµT z=%0.02fµT heading=%0.01f° status=%u", x, y, z, heading, status);`

			`if (this->x_sensor_ != nullptr)`
			`this->x_sensor_->publish_state(x);`
			`if (this->y_sensor_ != nullptr)`
			`this->y_sensor_->publish_state(y);`
			`if (this->z_sensor_ != nullptr)`
			`this->z_sensor_->publish_state(z);`
			`if (this->heading_sensor_ != nullptr)`
			`this->heading_sensor_->publish_state(heading);`
			`}`

			`bool QMC5883LComponent::read_byte_16_(uint8_t a_register, uint16_t *data) {`
			`bool success = this->read_byte_16(a_register, data);`
			`data = (data & 0x00FF) << 8 \| (*data & 0xFF00) >> 8; // Flip Byte oder, LSB first;`
			`return success;`
			`}`

			`} // namespace qmc5883l`
			`} // namespace esphome`